WO2012034885A2

WO2012034885A2 - Unit for heat, cold and electricity generation

Info

Publication number: WO2012034885A2
Application number: PCT/EP2011/065288
Authority: WO
Inventors: Bernd Gromoll; Johannes Reinschke
Original assignee: Siemens Aktiengesellschaft
Priority date: 2010-09-16
Filing date: 2011-09-05
Publication date: 2012-03-22
Also published as: WO2012034885A3; DE102010040882A1

Abstract

A unit (1) for heat, cold and electricity generation having an electrical machine (2) which is arranged between two Stirling machines (3A, 3B), wherein an armature (5) of the electrical machine (2) can be mechanically coupled via a first coupling device (4A) to a piston (8A) of a first Stirling machine (3A), and can be mechanically coupled via a second coupling device (4B) to a piston (8B) of a second Stirling machine (3B), wherein, in a first operating mode of the unit (1), and with electrical power being supplied to the electrical machine (2) as an electric motor after the mechanical coupling of the piston (8A, 8B) of at least one of the two Stirling machines (3A, 3B) by means of the respectively associated coupling device (4A, 4B) to the armature (5) of the electrical machine (2), the centrally arranged electrical machine (2) drives this at least one coupled Stirling machine (3A, 3B) in order to generate heat and/or cold, and wherein, in a second operating mode of the unit (1), and with external heat energy being supplied to this Stirling machine (3A, 3B) as the driving Stirling machine after the piston (8A, 8B) of the driving Stirling machine (3A, 3B) has been mechanically coupled by means of the associated coupling device (4A,4B) to the armature (5) of the electrical machine (2), one of the two Stirling machines (3A, 3B) drives the electrical machine (2) as an electricity generator for generation of electric power and, after mechanical coupling of the piston (8A, 8B) of the other Stirling machine (3A,3B) by means of the associated coupling device (4A, 4B) to the armature (5) of the electrical machine (2), additionally drives the other Stirling machine (3A, 3B) in order to generate cold.

Description

description

Aggregate for generating heat, cooling and electricity

The invention relates to a modular unit for ^{combin ¬} th heat, cooling and power generation.

In conventional units, as described for example in WO 2008/018806 AI, a reciprocating engine is coupled with a rotating electric machine, wherein the electric machine can be operated both as a motor and as a generator ^¬ .

However, such conventional units can only be used in a combined heat and power generation without the possibility of additional cooling to erzeu ^¬ gen. In many applications, however, it is desirable to provide a unit which is able, in addition to electricity also to generate heat and cold. For example, in the air conditioning of the passenger compartment of a vehicle or a living space, there is a need to heat or cool the passenger compartment or the living space depending on the ambient temperature.

It is therefore an object of the present invention to provide an aggregate which is suitable for the generation of heat, cold and electric current.

This object is achieved by an aggregate with the features specified in claim 1.

The invention provides an aggregate for generating heat, cold and electricity with:

An electric machine, which is arranged between two Stirling machines, wherein an armature of the electric machine via a first coupling device mechanically to a piston of a first Stirling machine and a second coupling Ein- direction is mechanically coupled to a piston of a second Stirling machine;

wherein in a first mode of operation of the unit, the centrally arranged electric machine when supplying electrical energy to the electric machine as an electric motor after suc ^¬ ter mechanical coupling of the piston of at least one of the two Stirling machines by means of the respective associated coupling device to the armature of the electric machine, this at least one coupled Stirling engine for generating heat and / or cold drives; and

wherein in a second mode of operation of the unit one of the two Stirling engines with supply of external heat energy to this Stirling engine as a driving Stirling engine after mechanical coupling of the piston of the driving Stirling engine by means of the associated coupling device to the armature of the electric machine, the electric machine as electric generator for generating electric current drives and

after the mechanical coupling of the piston of the other Stirling machine by means of the associated coupling device to the armature of the electric machine drives the other Stirling machine in addition to the generation of cold.

The aggregate according to the invention is preferably modular building up ^¬ and consists of an electric machine to which on at ^¬ the sides of a Stirling engine coupled is.

In one possible embodiment of the unit according to the invention, the armature of the electric machine oscillates in the first operating mode of the unit when electrical energy is supplied to the electric machine in the longitudinal direction with a ^certain natural frequency and displaces the mechanically coupled piston of the at least one coupled Stirling engine for generating Heat and / or cold in vibration.

In one possible embodiment of the unit according to the invention, the piston of the driving Stirling engine vibrates in the second operating mode of the unit when supplied from external heat energy to the driving Stirlingmaschi- ne with a certain natural frequency mechanically and offset the mechanically coupled armature of the electric machine for generating electrical current in vibration.

In one possible embodiment of the gregate according to the invention, the armature of the electric machine is suspended from at least one mechanical spring.

In a possible disclosed embodiment of the unit according to the invention, the mass of the armature of the electric machine and the mass of one or both mechanically coupled to the armature of the electric machine piston of the Stirling engine as well as the spring constant of the mechanical spring determine the Eigenfre ^acid sequence of the mechanical vibration.

In a possible imple mentation form of the unit according to the invention a Ausgleichsmas ^¬ se for adjusting the natural frequency of the mechanical vibration is provided at the anchor of the electric machine.

In a possible imple mentation form of the unit according to the invention, the two coupling devices are designed such that with the decoupling of the respective Stirling engine from the electric machine, a freely oscillating Ersatz ^¬ mass is coupled to the armature of the electric machine, where ^¬ is the same as the replacement mass moving mass of the previously coupled Stirling engine, so ^{sicherge ¬} is that does not change by connecting and disconnecting a Stirling engine, the natural frequency.

In a possible imple mentation form of the unit according to the invention, the two coupling devices are designed such that is decoupled with the coupling of the respective Stirling engine to the electric machine, the previously freely oscillating equivalent mass from the armature of the electric machine and mechanically connected to a stationary component. In one possible embodiment of the gregate according to the invention, the stationary component is a component which is fixedly connected to the stator winding of the electric machine.

In one possible embodiment of the device according to the invention, the two coupling devices can be operated manually.

In an alternative disclosed embodiment of the assembly according to the invention, the two coupling devices are ferngesteu ^¬ ert use.

In a possible imple mentation form of the unit according to the invention is carried out in a manually operable coupling device, the coupling of the anchor mass and the equivalent mass via screw or releasably mechanical locks, in particular snap closures.

In a further possible disclosed embodiment of the unit according to the invention in a remote controlled bedienba ^¬ ren coupling means coupling the armature mass and the equivalent mass by means of electromagnetic or piezoelectric actuators is made.

In one possible embodiment of the unit according to the invention, the natural frequency of the mechanical oscillation is 50 Hz or 60 Hz.

In one possible form of embodiment of the unit according to the invention, an electrical alternating current with a frequency of 50 Hz or 60 Hz is supplied to the electric machine in the first operating mode of the unit.

In one possible embodiment of the gregate according to the invention, a photovoltaic system supplies the electrical energy in the first operating mode. In another possible disclosed embodiment of the assembly according to the invention min ^¬ least one solar collector provides the external heat energy in the second mode.

The unit of the invention can be varied USAGE ^¬.

In a possible out guide assembly according to the invention will form used for an electric vehicle whose Fahrzeugak ^¬ kumulator in the first operating mode of the unit, the electrical energy to produce heat and / or cold providing for a passenger compartment of the electric vehicle and its Fahrzeugakkumulator in the second operating mode of the unit is charged by the generated by the pulse generator elekt ^¬ step current.

In a further possible embodiment of the disclosed embodiment of the unit according to the invention, the unit for a building verwen ^¬ det, the energy storage in the first mode of operation of the unit provides the electrical energy for generating heat and / or cold for living spaces of the building and its energy storage in the second Operating mode of the unit is charged by the electricity generated by the unit.

In another possible embodiment of the device according to the invention, the unit is used for a subscriber of a decentralized power network,

wherein the power network in the first operational mode of the unit provides electrical energy to produce heat and / or cold to the subscriber, and wherein the power network in the second operating mode of the unit electric Ener ^¬ energy has obtained from the aggregate of the subscriber.

In addition, possible embodiments of the device according to the invention for heat, cold and power generation are described in detail with reference to accompanying figures. Show it : Fig. 1 is a block diagram illustrating a possible

From leadership form of the unit according to the invention;

Fig. 2 is a diagram showing an embodiment of the unit according to the invention;

3A, 3B are drawings illustrating an embodiment of a coupling mechanism used in the unit according to the invention;

4 shows a block diagram for illustrating an application example for the unit ^according to the invention;

Fig. 5 is a block diagram illustrating another example of application for the Aggre ^¬ gat invention.

As can be seen from Figure 1, the unit 1 according to the invention for heat, cooling and power generation is modular ^¬ built and is suitable for combined heat, cooling and power generation. The unit 1 has in its center on an electric machine 2, which is arranged between two Stirling machines 3A, 3B. An armature of the electric machine 2 is mechanically coupled to a piston of the first Stirling engine 3A via a first coupling device and mechanically to the second Stirling engine 3B via a second coupling device.

The unit 1 of the invention can be switched between two Betriebsmo ^¬ d i. In a first mode of operation of the unit 1, the armature drives the centrally arranged electric machine 2 when supplying electrical energy from outside as an electric motor after mechanical coupling of the piston of at least one of the two Stirling machines 3A, 3B by means of the respective associated coupling device to the armature of the electric machine the at least one coupled Stir ^¬ ling machine 3A, 3B for generating heat or cold. In this first mode of operation, depending on the mechanical Ankopp ^¬ ment the centrally arranged electric machine 2 one or both Stirling machines 3A, 3B driven. One of the two powered Stirling engines can generate heat while the other powered Stirling engine generates cold.

In a second mode of operation of the unit 1 drives one of the two Stirling engines 3A, 3B with supply of external heat energy to this Stirling engine as a driving Stirling engine after mechanical coupling of the

Piston of the driving Stirling engine means of zugehö ^¬ ring coupling device to the armature of the electric machine 2, the electric machine 2 as an electric generator for generating electrical power. In this second operating mode, the piston of the other Stirling engine can additionally be coupled to the armature of the electric machine 2 by means of the associated coupling device. In this second Betriebsmo ^¬ dus additionally coupled second Stirling engine is additionally to generate refrigeration by the driving Stirling engine, which is supplied from the exterior thermal energy driven. The unit 1 according to the invention thus has various operating options.

In the first operating mode, the unit 1 is externally supplied with electrical energy or electric current, for example an alternating current AC with a frequency of 50 Hz or 60 Hz. In this first operating mode, therefore, the electric current is the primary energy source. After Ankopp ^¬ ment of the two Stirling machines 3A, 3B to the electrically driven electric motor or the electric machine 2, the unit 1 in this first operating mode either only generate heat or generate only cold or generate both cold and heat. Generated for example the first Stir ^¬ ling machine 3A, which is coupled to the electric machine 2, heat, and the second Stirling machine 3B, which is coupled to the Elek ^¬ tromaschine 2, cold, for the case that both Stirling machines 3A, 3B to the Electric machine 2 are coupled simultaneously, generating both heat and cold.

In the second operating mode of the unit 1, heat energy is supplied to the aggre ^¬ gate 1 from the outside, wherein this external heat energy can be generated for example by combustion of natural gas as a primary energy source. This heat energy is supplied to one of the two Stirling engines 3A, 3B as a driving Stirling engine. If the external heat energy is supplied to the armature of the electric machine 2, for example, the Stirling engine 3A as a driving Stir ^¬ lingmaschine after mechanical coupling of the piston of the Stirling engine 3A by means of an associated Kopp ^¬ treatment device, the electric machine 2 by the driving Stir ^¬ lingmaschine 3A as an electric generator powered to generate electricity. In this second operating mode, another Stirling engine 3B can additionally be coupled to the armature of the electric machine 2 by means of an associated coupling device. The driving Stirling engine 3A then operates not only the electric machine 2 as electric ^¬ generator for generating electrical power, but also the second Stirling engine 3B for generating cold or heat.

In the first mode of operation of the unit 1 of the An ^¬ ker of the electric motor 2 vibrates by supplying electric power to the electric machine 2 in the longitudinal direction with a certain natural frequency f mechanically back and forth. He puts the mechanically coupled piston of at least one coupled to the electric machine 2 Stirling engine 3A and 3B for generating heat and / or cold also in mechanical vibration. In one possible operating state, the armature of the electric machine 2 is coupled only to a piston of one of the two Stirling engines and causes it to vibrate a piston. In another operating state, the armature of the electric machine 2 is mechanically simultaneously at both pistons of the two Stirling engines 3A, 3B coupled and puts both pistons in mechanical

Vibration.

In the second mode of operation of the unit 1, the piston of the driving Stirling engine, such as the Stirling engine 3A, reciprocates upon supplying external heat energy to the driving Stirling engine 3A at a certain natural frequency f and displaces the mechanically coupled armature of the electric machine 2 to generate electric power Electricity also in vibrations. In this case, the armature of the electric machine 2 may be suspended from at least one mechanical spring. The mass of the armature of the electromag ^¬ machine 2 and the mass of the one or both of which is coupled to the armature of the electric machine 2 pistons of the Stirling engines 3A, 3B as well as the spring constant of the mechanical Aufhängefe ^¬ the thereby determine the natural frequency f of the mechanical vibration.

In a preferred imple mentation form of the unit 1 according to the invention is at the anchor of the electric machine 2, a compensation ^¬ equal mass for adjusting the natural frequency f of the mechanical vibration provided. The coupling means for coupling a piston rod of the Stirling machines 3A, 3B to the armature of the central electric machine 2 are configured at a mög ^¬ union disclosed embodiment such that with the Abkopp ^¬ development of the respective Stirling engine 3A, 3B by the electric motor 2, a free-swinging equivalent mass is coupled to the armature of the electric machine 2. The substitute mass is preferably the same size as the moving mass of the previously coupled Stirling engine 3A, so that it can be ensured in this way that the natural frequency f is not changed by coupling or decoupling a Stirling engine 3A, 3B.

The two coupling devices are preferably designed such that with the coupling of the respective Stirling machines 3A, 3B to the electric machine 2, the previously freely oscillating equivalent mass from the armature of the electric machine. ne 2 decoupled and mechanically connected to a fixed component of Ag ^¬ gregates 1. This fixed component is, for example, the holder of the stator winding of the electric machine 2.

The two coupling devices for coupling the two Stirling machines 3A, 3B to the centrally arranged electromag- netic machine 2 are manually operable in a possible embodiment. In the manually operable coupling device, it follows the coupling of the armature mass and the equivalent mass in ^¬ example, via screw. Alternatively, the coupling of the armature mass and the replacement mass can also be done via releasable mechanical locks, such as snap closures.

In an alternative disclosed embodiment of the unit 1 according to the invention, the two coupling devices for coupling the Stirling machines 3A, 3B to the electric machine 2 can be operated remotely. In this case, in one possible embodiment, the coupling of the armature mass and the substitute mass can take place by means of electromagnetic or piezoelectric actuators.

In one possible embodiment of the unit 1 according to the invention, the natural frequency f is the mechanical one

So that umrichterfrei connected in this case the invention ^shown SSE unit 1 to a power supply and power related or from the power supply can feed into the grid vibration 50 Hz or 60 Hz. This frequency corresponds to the mains frequency of a power grid, such as the public areas ^¬ chen power grid. In this embodiment, the unit 1 is supplied with an alternating current having a frequency of 50 Hz or 60 Hz in the first operating mode, the alternating current being applied to the electric machine 2. Conversely, in the second operating mode, the unit 1 supplies an alternating electric current with a frequency of 50 Hz and 60 Hz, which can be fed directly into an AC supply network of the same frequency. The unit 1 according to the invention thus allows advantageously a converter-free operation in all Be ^¬ operating modes.

Figure 2 shows an embodiment of the unit according to the invention 1. As can be seen from Figure 2, the two Stirling machines 3A, 3B can be coupled by means of coupling devices 4A, 4B to an armature 5 of the electric motor 2. The armature 5 has, for example, a jacket with magnets of different polarization. Further, the electric machine 2 has a stator 6A, 6B surrounding the armature 5. At the anchor of the electric machine 2, a balancing mass (not shown) may be provided, by means of which the intrinsic ^¬ frequency of the unit 1 can be adjusted. The armature 5 of the electric machine 2 is suspended in the form of embodiment shown in Figure 2 by means of mechanical springs 10A, 10B. By means of the coupling devices 4A, 4B, pistons 8A, 8B of the two Stirling engines 3A, 3B can be coupled to the armature 5 of the electric machine 2. The two Stirling machines 3A, 3B may each have an expansion space and a compression space, wherein the expansion space and the compression space are connected in the embodiment shown in Figure 2 to increase the efficiency in each case via a Re ^¬ generator 9A, 9B. In the expansion space of a Stirling engine, a heat exchanger for dissipating cold can be provided. In the compression space of a Stirling engine 3A, 3B, a heat exchanger for dissipating heat can be provided in each case.

The armature 5 of the electric machine 2 shown in Figure 2 oscillates in the first mode of operation of the unit 1 in Zu ^{¬ management} of electrical energy to the electric machine 2 in the longitudinal direction X with a certain natural frequency f mechanically back and forth. The reciprocating armature 5 also causes the mechanically coupled pistons 8A, 8B of one or both of the Stirling engines 3A, 3B to vibrate mechanically. Conversely, if a piston 8A of a driving Stirling engine, such as the Stirling engine 3A, mechanically via the associated coupling device 4A connected to the armature 5 of the electric machine 2, the piston 8A of the driving Stirling engine 3A mechanically oscillates with external heat energy to the driving Stirling engine 3A with a certain natural frequency f and offset the mechanically coupled via the coupling device 4A anchor 5 of Electric machine 2 for generating electric current in oscillation. The natural frequency f of the mechanical oscillation is determined by the mass of the armature 5 of the electric machine 2, including optionally mounted on the anchor 5 balancing mass, and by the mass of one or both of the armature 5 of the electric machine 2 mechanically coupled piston 8A, 8B of the Stirling engines 3A, 3B and the spring constant in the longitudinal direction x of the two suspension springs 10A, 10B determined.

The two coupling devices 4A, 4B are preferably designed such that with the decoupling of the respective Stirling engine 3A, 3B from the electric machine 2 a freely oscillating equivalent mass 7A, 7B is coupled to the armature 5 of the electric machine 2. This equivalent mass 7A, 7B is preferably as large as the moving mass of the previously coupled ^¬ Stirling engine 3A, 3B, that is, as large as the mass of the corresponding piston 8A, 8B. In this way, it is ensured that the egg ^¬ genfrequenz f of the mechanical vibration is not changed by connecting and disconnecting a Stirling machine 3A, 3B to or from the electric machine 2. When a Stirling machine 3A, 3B is coupled to the electric machine 2, the previously freely oscillating substitute mass 7A, 7B is in turn decoupled from the armature 5 of the electric machine 2 and fixed with a stationary component, for example with the holder of the stator winding 6A, 6B of the electric machine 2 connected. The coupling devices 4A, 4B shown in FIG. 2 can be operated manually or remotely.

Figures 3A, 3B show exemplary embodiments for Ausgestal ^¬ tung the coupling means 4A, from in the illustrated in Figure 2 4B guide shape of the aggregation of the invention FIG. 3A shows a coupled state in which the rod IIB connected to the armature 5 of the electric machine 2 is connected to and coupled to a piston rod 8B of the Stirling engine 3B. Figures 3A, 3B show the development of the second Ankopp- in Figures 1, Stirling machine shown on the right 2 3B constructed analogously in a symmetrical manner to the electric machine 2. The coupling ^{mechanism at} the illustrated left first Stirling engine 3A to the electric machine. 2 In the illustrated by Figure 3A, 3B embodiment, the coupling takes place with the aid of a coupling sleeve ^¬ 12B. This coupling sleeve 12B may be a tube with an internal thread, as indicated in FIG. The coupling collar 12B each includes a threaded end portion of the anchor rod IIB connected to the armature 5 and the piston rod 8B. In the coupled state, a replacement mass 7B is decoupled from the anchor rod IIB of the armature 5 and connected to a fixed component, which may be a holder or a housing part of the electric machine 2. In the illustrated embodiment in Figure 3 is at the equivalent mass 7A, 7B, a ring ticket ^¬ be with an internal thread, which is connected to a support or a fixed member 13B of the electric machine. 2

FIG. 3B shows the decoupled state of the coupling device 4B. When decoupling the Stirling engine 3B from the

Electric machine 2, the free-floating spare mass 7B is coupled to the armature 5 connected to the anchor rod IIB, as can be seen in Figure 3B. The equivalent mass 7B is preferably equal to the moving mass of the front ^¬ forth coupled in the coupled state Stirling machine 3B, so that the natural frequency f of the mechanical vibration is not changed by the detachment of the Stirling machine 3B. In a further disclosed embodiment, the mechanical vibration is maintained in this way at a constant Schwingfre ^¬ frequency of 50 Hz or 60 Hz. The unit 1 of the invention can be varied Einset ^¬ zen. 4 shows an example of application of the inventive unit 1 for a building 14. The electric machine 2 of the unit 1 is connected via a DC / AC converter 15 to a photovoltaic system 16. Furthermore, the unit 1 is connected to a solar collector 17, which can deliver external heat to the unit 1 when exposed to sunlight. The unit 1 according to the invention can provide heat and / or cooling in the building 14 to a room 18 in which, for example, a person 19 is located. Via a controller 20, an operating mode of the unit 1 can be set. In the ers ^¬ th mode of operation of the unit 1 the unit 1 is supplied by the photovoltaic system 16 electrical energy which is converted by the pulse generator 1 in the heat and / or cooling for the room 18th In the second operating mode the Ag ^¬ gregat 1 is supplied through the solar panel 17 external heat energy, which is converted by the unit 1 into an electric current, for example by a be ^¬ find pending in the space 18 electrical device 21 is driven. The device 21 may be a lamp or ^¬ same, for example. The current generated when external heat W is supplied can alternatively be stored in an energy store, for example a current accumulator, for the later

Consumption be saved.

The unit 1 illustrated in Figure 4 can thus heating or in the ers ^¬ th mode of operation upon application of electrical energy which is supplied for example by the photovoltaic system 16 or is obtained from a previously charged power storage 22, the space 18, for example, in winter, for example, cool in the summer. Furthermore, when power is supplied in the first operating mode, the unit 1 can cool a first room, for example a food storage room, and at the same time heat another room of the building 14 in which persons are located. Furthermore, the unit 1 shown in FIG. 4 can, in the second operating mode, be supplied with external heat energy, for example from the solar collector shown in FIG. 4, the building 14 Cool or warm and at the same time supply electricity for Haushaltsgerä ^¬ te, in particular the lighting, or store the electricity in an accumulator.

Figure 5 shows a further application example for the dung OF INVENTION ^¬ contemporary unit 1. In the illustrated application example, the unit 1 is installed in an electric vehicle 21, and can provide heat or cold in a passenger compartment 24 of the electric vehicle. A driver 25 may, for example, via a controller 26, the operating mode of the unit 1 ^¬ SET len. The unit 1, for example, heat energy can be ^¬ leads, which comes from a combustion or electric motor 27 of the vehicle 23. An AC / DC-coupler 28, the unit 1 may be connected to a Fahrzeugakkumulator 29 of the Fahrzeu ^¬ ges 23rd Heat energy is supplied to the accumulator 1 in the second operating mode, and the alternating current generated by the aggre ^¬ gate 1 can be converted by the AC / DC converter 28 into direct current, through which the vehicle battery 29 is charged. Conversely, the information stored in the Fahrzeugakkumulator 29, electrical energy can be used in the first operation mode of the unit 1 of this gene with electric power to versor ^¬.

The unit 1 according to the invention can be used in a further ^embodiment for a subscriber of a decentralized power network. Here, the current network in the first mode of operation of the unit 1 supplies electric power to generate heat and / or cold in the jewei ^¬ time subscriber. Furthermore, in the second operating mode of the unit 1, the power network can draw electrical energy from the unit 1 of the respective subscriber.

The unit 1 of the invention is also suitable for Küh ^¬ ment or heating of buildings. Further, any fluid in the ers ^¬ th mode of operation can be warmed or heated by the inventive aggregate. 1 The erfin ^¬ tion proper aggregate 1 is thus universally applicable and is particularly suitable for stand-alone systems that require a self-sufficient supply of heat, cold and electricity.

Claims

A generator (1) for generating heat, cooling and electricity, comprising: an electric machine (2) which is arranged between two stirring machines (3A, 3B), wherein an armature (5) of the electric machine (2) has a first Kopp ^¬ averaging means (4A) mechanically connected to a piston (8A) of a first Stirling engine (3A) and a second coupling means (4B) mechanically connected to a piston (8B) of a second Stirling engine (3B) can be coupled;

wherein in a first operating mode of the unit (1), the centrally arranged electric machine (2) upon supply of electrical energy to the electric machine (2) as an electric motor after mechanical coupling of the piston (8A, 8B) of at least one of the two Stirling machines ( 3A, 3B) by means of the respective associated coupling device (4A, 4B) to the armature (5) of the electric machine (2) drives this at least one coupled Stirling engine (3A, 3B) for generating heat and / or cold; and wherein in a second operating mode of the unit (1) one of the two Stirling engines (3A, 3B) upon supply of external heat energy to said Stirling engine (3A, 3B) as a driving Stirling engine after mechanical coupling of the piston (8A , 8B) of the driving Stirling engine (3A, 3B) (via the associated coupling means 4A, 4B) (to the anchor 5) of the electric motor (2) drives the electric machine (2) as an electric generator for the generation ^¬ supply of electric current and

after mechanical coupling of the piston (8A, 8B) of the other Stirling engine (3A, 3B) by means of the associated coupling device (4A, 4B) to the armature (5) of the electric machine (2), the other Stirling engine (3A, 3B ) in addition to generating cold.

2. Unit according to claim 1,

wherein the armature (5) of the electric machine (2) in the first operating mode of the unit (1) for supplying elec ^¬ tric power to the electric machine (2) in the longitudinal direction with a certain natural frequency (f) mechanically vibrates, and the mechanically coupled piston ( 8A, 8B) of the at least one coupled Stirling engine (3A, 3B) for generating heat and / or cold vibrated.

3. Unit according to claim 1 or 2,

wherein the piston (8A, 8B) of the driving Stirling engine (3A, 3B) in the second operating mode of the Aggre ^¬ gates (1) with supply of external heat energy to the driving Stirling engine (3A, 3B) with a specific natural frequency ( f) vibrates mechanically and causes the mechanically coupled armature (5) of the electric machine (2) to generate electrical current in vibrations.

4. Unit according to claim 1 to 3,

wherein the armature (5) of the electric machine (2) is suspended from at least one mechanical spring (10A, 10B).

5. Unit according to claim 4,

wherein the mass of the armature (5) of the electric machine (2), the mass of one or both of the armature (5) of the electric machine (2) mechanically coupled piston (8A, 8B) of the Stirling engine (3A, 3B), the Mass of Kopp ^¬ ment device (4A, 4B) between the armature (5) and piston (8A, 8B) and the spring constant of the mechanical spring (10A, 10B) determine the natural frequency (f) of the mechanical vibration.

6. Unit according to claim 5,

wherein the anchor (f) is provided of the mechanical vibration (5) of the electric machine (2) from a ^¬ equal mass to adjust the natural frequency.

Aggregate according to claims 2 to 6,

wherein the two coupling devices (4A, 4B) are designed such that with the decoupling of the respective Stirling engine (3A, 3B) of the electric machine (2) an equivalent mass (7A, 7B) to the armature (5) of the Elektroma ^¬ machine (2) is coupled, wherein the replacement mass (7A, 7B) free swinging and the same size as the moving mass of the previously coupled Stirling engine (3A, 3B), so that it is ensured that by coupling on or off ^¬ a Stirling machine (3A, 3B) the Eigenfre ^¬ frequency (f) does not change.

Aggregate according to claim 7,

wherein the two coupling means (4A, 4B) are designed such that with the coupling of the respective Stirling engine (3A, 3B) to the electric machine (2) the previously freely oscillating spare mass (7A, 7B) of the armature (5) of Electric machine (2) uncoupled and with a fixed component (13A, 13B) of the unit (1) me ^¬ chanically connected.

Aggregate according to Claim 8,

wherein the fixed member (13A, 13B) is a member fixedly connected to the stator winding (6A, 6B) of the electric machine (2).

Aggregate according to claims 2-9,

wherein the two coupling means (4A, 4B) are manually or remotely operable.

Unit according to Claim 10, having a manually operable coupling device (4A, 4B),

wherein the coupling of the armature mass and the replacement mass (7A, 7B) via screw or releasable mechanical locking takes place.

Unit according to Claim 10, having a remote-controlled coupling device (4A, 4B),

wherein the coupling of the armature mass and the replacement mass (7A, 7B) by means of electromagnetic or piezoelectric actuators takes place.

13. Unit according to claim 2 to 12,

wherein the natural frequency (f) of the mechanical vibration is 50 Hz or 60 Hz.

14. Unit according to claim 11,

wherein in the first operating mode of the unit (1) of the electric machine (2) an alternating electrical current (AC) with a frequency of 50 Hz or 60 Hz is supplied.

15. Unit according to claim 1 to 12,

wherein in the first operating mode of the unit (1) a photovoltaic system supplies the electrical energy.

Aggregate according to claims 1 to 12,

wherein in the second mode of operation of the unit (1) at least one solar panel provides the external heat energy. 17. The use of the unit according to claim 1 to 12 for an electric vehicle, the vehicle battery in the first operating mode of the unit (1) provides the electrical energy for generating heat and / or cold for a passenger compartment (24) of the electric vehicle (23) and its Fahrzeugakkumulator (29) is charged in the second mode of operation of the unit (1) by the power generated by the unit (1).

Use of the unit according to claim 1 to 12 for a building (14), the energy storage in the first operating mode of the unit (1) provides the electrical energy for generating heat and / or cold for living spaces (18) of the building (14) and its energy storage in the second mode of operation of the unit (1) is charged by the electrical current generated by the unit (1). 19. Use of the unit according to claim 1 to 12 for

a subscriber of a decentralized power network, wherein the power network in the first operating mode of the unit (1) provides electrical energy for generating Wär ^¬ me and / or cold at the subscriber, and

the power network being in the second mode of operation of the

Aggregates (1) relates electrical energy from the aggregate (1) of the subscriber.